Control for motor vehicle transmissions



Dec. 16, 1952 o. w. SCHOTZ CONTROL FOR MOTOR VEHICLE TRANSMISSIONS Filed Sept. 21, 1946 4 Sheets-Sheet l Jar v I INVENTOR. 1 SclzofZ.

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Dec. 16, 1952 o. w. SCHOTZ CONTROL. FOR MOTOR vsmcu: TRANSMISSIONS Filed Sept. 21, 1946 INVENTOR W Scfiozz HTTORNL'YS Dec. 16, 1952 o. w. SCHOTZ 2,621,525

CONTROL FOR MOTOR VEHICLE TRANSMISSIONS Filed Sept. 21, 1946 4 Sheets-Sheet 5 A \W; .53 1 67 .52 I go I I F ll I I 2 VIII/111513711117, /23 8 4 INVENTOR.

E T Otto W SchofZ.

W M M Dec. 16, 1952 o. w. SCHOTZ CONTROL FOR MOTOR VEHICLE TRANSMISSIONS 4 SheetsSheet 4 Filed Sept. 21, 1946 INVENTOR. OH'o W -S'c kozz UNITED FFIE ()ONTROL. FOR MOTOR VEHICLE, TRANSMISSIONS Otto W. Schotz', Detroit, Mich, .assignorto Chrysler Corporation, Highland-Park, Micin, acorporation of Delaware Application September 21, 194a seria1noi 693,451-

3 Claims.

This invention relates to automotive vehicle transmission controls and more particularly. to automatic. means for-changing the-speed Eratio drive of the transmission.

An automatic transmission control is de-v scribed and claimed in application Serial No. 661,298 filed April 11, 1946, by C. A. Neracher and Maurice C. Robinson. Thepresent invention is adapted to perform similar functions-to thoseperformed by the apparatus in the above application, Serial No. 661,298. However, the apparatus described in that application utilizes a vacuum cylindcr that has suitable valving to. effect. move ment of a piston in either of two. directions by vacuum. This type of vacuum cylinder is usually referred tons a :doubleacting? cylinder. present invention is designed to use a-.single acting? vacuum cylinder and piston :to actuatethe transmission control.- In a .singleacting sys tem the piston is moved in one direction; by vac-- uum and returned by a spring; This fundamental difference in cylinder and piston construction is important inthatthe entire cycle of operation of the apparatus is changedthereby.

The piston of a double acting system moves in a first direction to'effectone speed ratio-drive and in another direction to effect a second speed. ratio drive. The piston of a single acting? systemmakes the same movement when; either-speed ratio drive: is effected; The piston moves in a first. direction and is returned to-its. original sition for each change "of speedratio-fdrive-r, In

the -double. acting system. thedirection of movement of the piston determines. which speedratior drive will be obtained; In. the single acting? sys tem the movement of the piston is always the same (advance and return) and; auxiliary means.

frequently referred. .toas an alternator mecha-c ni'sm, determines which-speed ratio 'drive will bee obtained."

Both apparatuses are responsive to. driver Sig-.-

nal as, for example, by. throttle "closingawith'm; predetermined vehicle speed limits to. initiate --a cycle including a clutch disengagement achangein transmission speed .ratio drive anda clutch reengagement.

The single-acting system possesses advantages in the elimination of valves and .thefact; that movement of the piston in one directionis' avaih able for disengaging the: clutch and movement of l the piston in a second direction" tthe spring: reiturn) is available for reengagingthe clutch;- In the double actingsystem. movement of theepi'ston in one" direction must accomplish both-oi these actions as well as :ch'ange-thespeed 'ratid The.

21' drive in the transmission.- Theproblein of timin becomes acute in. a double. acting system. Inthe drawings: Fig. Lisa-vertical section of a fluid drivean clutch assembly;

Fig zi's' ayerticalsection of. a transmission; Fig. 3 .is a diagrammatic view of the entire 8Y5!- tem;'

Fig. 4 is a. sectional elevational view of a poretional type of. friction main clutch- 22 through shaft 23 to a variable speed ratio transmission 2 1 from which the-drive passes from the output shaft to the vehicle rear wheel in the *usual manner The engine crankshaft -1 carries the varied fluidvcouiplingv impeller. 26" which the-,- wellknown manner. drives the. vaned. runner 21 whence the drive passes througlrhubcza to clutch driving-member 29 This member then transmits the driveqwhen clutch 22. is'eng ed as in.Fig-.; 1,:

through. driven: member 30: to the transmission driving; shaft 23 carrying the maindrive. pinion 3 2.- A clutch pedal 33 controls clutch 22 such that. when theidriver depresses this pedal yoke- 34 and collar 35 are thrust.- forward to cause. levers:- 35

to release the clutch driving pressure-plate 31. against springs ill! thereby releasing the drivebetweenrunner 2-1 and shaft 23. The primary function of the main clutch 22 is to enable shifts .to be mademanually or automatically intrans-i mission 24.; The reasons; forthe use of a; fluid-- coupling are-explained in applieatiomserial No: 661,298, by Carl AiNeracherand Maurice-C. Robv inson:

Referringto-thetransmission in Fig .v 2 the main drive pinion: :32 isin constant :meshwith:

the gear ofl thercountershaft gear: cluster mounted i for rotation on the counters'haft This gearclnster according to well known prac.-'

tice, comprises a low speed-gear; a; second speed gear 43, and a reverse gear 44 which is in constant mesh with the reverse idler gear 45. The transmission driven shaft extends rearwardly to drive the ground wheels of the vehicle.

The driven shaft 25 has mounted thereon the low speed. and reverse gear 41 splined to the driven shaft for selective meshing with the countershaft low speed gear 42 or the reverse idler gear 45 for respectively transmitting low speed drive to the driven shaft 25 or the drive thereto in a reverse direction. Freely rotatable on shaft 25 is the second speed gear 48 in constant mesh with the countershaft gear 43 for transmitting a second speed ratio drive. The gear 32 drivingly carries a set of circumferentially spaced external clutch teeth 49. In a similar manner the gear 48 drivingly carries a set of clutch teeth 59.

Splined on the shaft 2-5 adjacent the forward extremity thereof, is an axially shiftable collar or sleeve 5i. Blocker teeth rings 52 and 53 are carried by sleeve 5| and are provided with friction means (not shown) adapted to selectively cooperate with friction means provided with teeth 49 and 50. The blocker teeth rings 5 and 53 are. adapted for. slight rotation relative to sleeve 5i to facilitate synchronizing of gear speeds prior to clutching of shaft 25 through collar 51 with either gears 52 or 48 in a manner Well known in the art.

The transmission is illustrated in its neutral position. To establish the direct or high speed driving connection between shafts .23 and the collar 5! may be shifted axially to the left as viewed in Fig. 2 by the control means hereinafter described to engage the teeth 49 drivingly connected to the gear 32 carried by the driving shaft 23. The collaris drivingly carried by the shaft 25. The second speed driving connection is established by similarly moving the collar 55 to the right as viewed in Fig. 2 to engage teeth 5.? carried by gear 43. The first or low speed is obtained by moving gear 41 which is splined' to driven shaft 25 forwardly in Fig. 2 into engagement with the countershaft low speed gear 42. The drive then occurs from shaft 23 through main drive pinion 32, countershaft gear 45, countershaft low speed gear 42, gear 41, and driven shaft 25. Reverse drive is obtained by engaging gear 41 with reverse idler gear 45. The transmission mechanism thus described is an embodiment' conventionally employed in motor vehicles.

Transmission 24 is provided with control means comprising selector cam 55 keyed to shaft 55 which is keyed to selector lever 51. Rotation of selector lever 51 rotates cam 55, the outward end of cam 55 is lifted by this movement (see Figs. 4 and 5). Control shaft 58 (Fig. 4) is rotatably mounted in the transmission housing. Cylindrical'lever 59 surrounds shaft 58 and pin 55 moun ed normally to the axisof theshaft fastens the lever to the shaft. Relative axial rotation is prevented by pin 60' but slight rotation of lever 59 on illustrated in Fig. 4, finger BI is normally in engagement with the fork 63 on the second speed and direct drive shift rail. 4

In operation, finger Bl is lifted or lowered to select the fork 62 or 63 which finger Si is to move. Rotation of shaft 58, cylindrical lever 55, and finger 5! moves the selected shift rail, fork, and collar to the left or right in Fig. 2 depending upon the direction of rotation of shaft 53. A shiftable control element in the ---form of a lever 59 is provided and keyed to shaft 58 to rotate the latter.

Manual means are provided in the apparatus illustrated in Fig. 3 for the operation of the clutch and control of the transmission speed ratio drive. The clutch pedal 33 is rotatably mounted at it on .a shaft, not shown. An extension 23 of clutch pedal 33 depends below rotatable mounting 1-3 and has fixed thereto a pin H. A torque shaft l2 has one end thereof rotatably mounted on the vehicle frame, not shown, and the other end rotatably mounted adjacent the engine block, not shown, in a manner well known in the art.' An arm 1? is keyed to shaftlZ. A rod 79 operatively connects pin 78 on arm ll with pin '7: on clutch pedal 3-3. A slot 88 provided in rod it) permits relative movement in one direction be tween rod 79 and pin 15." An arm '13 is keyed to torque shaft 12. A, rod 15 connects arm 13 with clutch throwout fork 18 which is pivoted atl'E'. Clutch throwout fork 16 engages collar 34. (Fig. l). pedal 33 rotates extension 33 about rotatable mounting l0 and through pin it retracts rod l5 and rotates arm ll, shaft 12 and arm l3 to push the rod 15 and rotate clutch throwout fork about its pivotal mounting is thereby moving collar 34 and disengaging the clutch 22.

A manual shift control rod 82 is shown in Fig. 3

as supported by the steering column housing 83' by bracket 84. The manual shift control rod 82' is slidably mounted in the bracket 54 and adapt-- ed for both axial and rotary movement. As is usual in the art, the axial movement is adapted to' selectthe transmission shift rail 64 or 65 which is to be moved by finger 6| (Fig. 4.), and rotation of the shift control rod 82 slides the shift rail in one of two directions (depending upon the direction of rod rotation) through the rotation of shaft 58 (Fig. 4) as described above. This effects the desired transmission speed ratio drive con-' nection. A pair of spaced circumferential collars 85 and 86 located adjacent the base of rod 82 receive therebetween the end of a lever Bl which is rotatably mounted adjacent its mid" portion to the steering column housing 83. A rod 88 connects lever 8'1 with transmission selector lever 57.

An arm 89 is keyed to rod 82. A depending rod 92 connects 'rod 9| with a rotatable lever 93' mounted on shaft 94. A rod 96 connects an arm 95 of lever 93 with means to be described and which is associated with transmission shift lever 55. described rotates shift lever 69 and shaft 58 (Fig. 4) for manual transmission control.

Referring to Fig. 3, an automatic transmission control which has been superimposed upon the It will thus be seen that depression of clutch- Axial movement 'of rod 82 is trans-- mitted through this linkage to the selector lever' Rotation of rod 82 through the linkage just A piston H9 is slidably mounted in cylinder I87 and a spring .H l

acting-on piston I'Illiand reacting on housing I08 urges. piston lid to one end of cylinder Iill'I. Manifold low pressure or vacuum as it is commonly referred to, overcomes spring I when valve I09 is open. A power operated member in. the form of a piston rod I:I2 has a rod II3 ro tatably secured to one end thereof. Rod H3 is connected by pin H4 with an arm II5 rotatably mounted on torque shaft I2. The. arm. H5 is provided with an extension I I6 adapted to engage the arm I3 when arm I I5 is rotated in a counterclockwise direction. When cylinder IO'I is connected with the manifold through valve I39 and tubular passage I08, piston III} is moved to the right in Fig. 3 and piston rod. I1I2 pulls on arm. H3 which rotates arm H5 in a counterclockwise direction. The. extension IIS on arm II5 engages and carries therewith the arm I3. Rotation of the arm I3 pushes rod I5, rotates clutch throwout fork I6, and disengages the clutch 22. The rotation of the arm T! in this counterclockwise direction does not cause a depression of the clutch pedal 33 because of the cooperation of the slot 80 in rod I9 and the pin I8. This pin and slot combination permits counterclockwise rotation of arm I! in Fig. 3 without an accompanying depression of clutch pedal 33. When valve I09 closes cylinder H3 1 to the manifold and vents the cylinder, spring III returns the parts described to their original position permitting the clutch to reengage. Clutch springs 38 supply the force forclutch reengagement.

The movement of piston I I also eifects changes in transmission speed: ratio drive by the movement of transmission collar illustrated in Fig. 2. Theautomatic apparatus herein effects changes of speed ratio drive between a relatively slow drive of the driven'wheels and a relatively fast drive or between second and direct drive as particularly described in relation tothe Fig. Z'transmission. An abutment 8 is rigidly secured to piston rod 2.. A member 9 is slidably mounted on piston rod II2 for axial movement relative thereto and restrained against rotation relative t'o'rod M2 by a conventional keyway (not shown). A spring III is concentric with red H2 and abuts against abutment 8 and member 9. The member 9 is adapted to actuate an alternator mechanism which includes a rotatably mounted toothed member in the form of a pinion I I8: which is rotatably mounted at H9 and carries four pins I which project laterally from one face thereof and parallel the axis of the pinion. A second rotatably mounted toothed memberin the'form of a pinion I2I having a circumference'ofsubspring I28 which reacts against pawl IESurging" it to rotate in a counterclockwise direction until it engages an abutment I29 on member 9. Movement of the piston I It to the right in Fig. '3 under the influence of manifold suction moves abutment 8 to the right thereby compressing spring I I? and The pawl I25,-

urging member 9 to the right. which is in engagement with a pin I29, is pre-- vented from. rotating ina counterclockwise direc tion by the. abutment I219v and, therefore, forces thepawl [20 to accompany itinitsmovementtoward the right in Fig. 3- A complete stroke of piston I:I0' will thus cause approximately onee quarter of a revolution of pinion I18; The one-quarter revolution of pinion I I8 will, because of the relative sizes of the pin-ions H18 and HI; cause approximately one-half of a revolution of pinion- I2I:. The one-half revolution of pinion. IN is sufficient to move the link I23 to the right, a. distance corresponding to twice the radinsoi the point on pinion I2I at which link I 23 isrotatably mounted. This; movement. of I23 to the right. is transmitted through :they second member 1:24 and link. I25 to transmission'shift lever 691whi'ch causes shaft 58' inFig. 4: to rotate and move collar: 51 in a. manner previously described to e'ilect. at: change in speed ratio drive in the transmission; The disengagement. of clutch 22 wasvprevi'ously described. as an incident to motion of pistonilfll It is to be understood that the disengagement of clutch. 22' and movement of transmission :shift lever 618 are both occasioned by movement of' piston Hi] to the right in Fig.3. The spring- I'IT permits a slight delay to occur after the :piston motion. has begun and before. movement. of mem: her. 9 is initiated. The clutch disengagement occurs during this. interval, when. the piston III! has completed its movement. to the right and the valve 09 is closed to the. manifold and vented to the atmosphere by means to be described herein. The spring III forces piston I III to return to the position illustrated in Fig. 3' at the left: end of the cylinder I06. This return. motion: of'the:

piston permits the clutch pressure springs 38 to reengage the clutch and the motion of the. abutment '3. to the left relaxes. the compression of" spring I. I1 and permits member 9 to move to the left. Pawl I26 does not: restrict the movement of member 9 because of its rotatable mounting at I21 and the resilient nature of spring. I28; Pawlv I26 is able to snap over the pin I20 located inthe lower left quadrant of the pinion I I8. It shou ld be noted that the return motion of piston I'III" under the influence of spring II I caused no rotation of pinion II 8 or the associated pinion I2I and link I23. When the link I23. is positioned as around the pinion I2 I.

link I23 to the left approximately to return it to the position illustrated in Fig. 3. Successive movements of piston. I I!) to the. right cause'rotation of transmission lever 69 in tions.

Referring to Figs. 7 and 8, the second member I24 previously referred to w-illbedescribed. member is adapted to select between manual or" automatic movement of transmission shift-lever:- G9. The second member I24 comprises-a housing. I39 having parallel tracks I3I and I32. The rod 96 previously referred to as a component of the" manual linkage, is slidably mounted. in track I3I A rod I33 operatively connectedt'o the-link. (23 of L the automatic control, is sli'dably mounted in track I32. Each of these rods, 96 and I33 are provided with a lateral notch so positioned' thatthe notches are aligned when both tIieniariuai and. automatic systems are-in second" speed post l posit'e direct,-

7 tion. A gate I34 is rotatably mounted at I35 and extends laterally of the housing I30. Rotation of the gate I34 about point I35 is-used to selectively couple rod 96 or rod I33 with housing I30 by the engagement of the gate I34 with the notch in one of the rods. A solenoid I36 carries a plunger I31 located above the gate I36. A spring I38 urges the gate to rotate to the position illustrated in Fig. 8 in which the rod 96 is operatively connected to the housing I30 for manual control. Under these conditions the solenoid I36 is deenergized. When the solenoid I36 is energized, the plunger I31 rotates the gate I34 in a counterclockwise direction and overcomes the spring I38 to operatively connect the rod I33 with the housing I30 for movement of the housing I30 as an incident to the automatic impulse imparted by the link I23. The housing I30 carries the link I25 which is operatively connected to the transmission shift lever 69. Thus the solenoid I36 determines whether the manual rod 96 or the automatic rod I33 will impart motion to the housing I30, link I25, and transmission shift lever 69. In automatic operation the link I25 is alternately pushed and pulled by the housing I36. Thus each successive movement of piston I I6 induces a motion of shift lever 69. These successiv motions alternate between clockwise and counterclockwise rotation of the shaft 58. The spring 66 in Fig. 4

urges the finger 6| into engagement with the shift rail 65 at all times when the selector lever 51 is not actuated. During automatic control the selector 51 is not actuated. Therefore, the successive clockwise and counterclockwise motions of shift lever 69 cause the shift rail 65 to move alternately to the left and to the right in Fig. 6 thereby moving the collar I to the left and to the right and causing alternate drives to occur in second speed or direct drive in the transmission of Fig. 2. Carburetor throttle lever I50 is controlled by accelerator pedal I5I through conventional linkage illustrated as rod I52 in Fig. 3. Rod I52 connected to accelerator pedal I5I has its other end connected to lever I50 rotatably mounted on carburetor I49. Thus actuation of accelerator pedal I5I through rod I52 rotates throttle lever Means to control the actuation of the piston I I6 is illustrated in Fig. 3. The automatic means depends for actuation upon the closing of the I switch 91 which is provided adjacent the base of rod 82. An arm 98 secured to the base of the shift control rod 82 is so positioned that when the rod 82 is lowered and rotated into the usual second speed position, the switch 91 is closed. A dash switch 99 is also provided for driver control of the selection of automatic drive.

A grounded source I60 of electric energy is connected through ignition switch I6I to dash selector switch 99. Two grounded circuits emanate from switch 91. The first circuit comprises conductor I62 connected to switch 91 which is adapted to be closed when the shift control rod 82 is placed in a predetermined position as described above. Electrical line I63 connects switch 91 with solenoid I36 which was previously described with reference to member E24. Conductor I64 grounds solenoid I36. The other circuit includes switch I59 adapted to be closed when the throttle is substantially closed. Line I56 connects switches 99 and I59. A two-way shift rail switch I66 having a finger I61 thereon adapted to be engaged by abutments on an extension I68 of the transmission shift rail 65 is provided. A first circuit in switch I66 is disconnected and a second circuit is connected when the shift rail has completed its movement. This switch movement alternates with each transmission speed ratio change on the shift rail 65. A vehicle speed responsive governor I69 has one inlet terminal I10 and two outlet terminals HI and I12 and is adapted to connect the inlet terminal with one outlet terminal below a predetermined speed and with the other outlet terminal above the pre determined speed. Each outlet terminal is connected to one of the circuits referred to for switch I66. The inlet terminal of governor I69 is connected to throttle switch I59 by line I65. Line I13 connects the outlet terminal of switch I96 with solenoid valve I09 in manifold line I08. Line I14 grounds the circuit. Valve I09 is adapted to connect cylinder I01 with the manifold line I68 when energized and to close line I06 and vent cylinder I01 to atmosphere when not energized.

In the operation of the apparatus thus far described when the driver closes switches 91 and 99 to select automatic drive and then closes the throttle lever I59 above a predetermined vehicle speed, valve I09 is energized to admit vacuum to cylinder I01. Piston H0 is moved to the right in Fig. 3 and clutch 22 disengaged through the linkage H2, H3, H5, collar 13, rod 15, and clutch throwout fork 16. This action of the piston also causes a delayed movement of transmission shift lever 69 and shift rail through abutment 6, spring II1, member 9, pawl I26, pinion H8, pinion I2I, link I23, member I24, and link I25. The movement of shift lever 69 moves the shift rail 65 and its extension I68 breaks the circuit at switch I66 thereby deenergizing solenoid valve I09 and permitting spring I I I to move piston I I0 to the left end of the cylinder permitting the clutch to reengage. The switch I66 is now connected with its other circuit and a complete electrical circuit will be made when the governor I69 connects the inlet terminal I16 with the other outlet terminal below a predetermined vehicle speed and the driver closes the throttle switch I59 by releasing accelerator pedal I5I. The electrical circuit then being complete the solenoid valve l 09 is energized and the piston IIO again moved to the right to repeat the process. The pinion I2I will this time move the transmission shift lever 69 in the reverse direction from that previously experienced. The shift rail 65 will be moved and the collar 5| moved to cause a second speed drive in the Fig. 2 transmission.

Figure 9 illustrates a modified mechanical connection between the vacuum cylinder and clutch and between the vacuum cylinder and transmission shift lever. The electrioal control apparatus has been omitted from the Fig. 9 diagrammatic showing for simplicity. The vacuum cylinder I01, piston IIO, and spring III are substantially the same as that illustrated in Fig. 3. The piston rod 2' is rotatably connected at 200 with a rotatable lever 20 I Lever 20I is rotatably mounted on a shaft at 202. A link 203 is rotatably mounted on lever 20I between the points 200 and 202 and operatively connected with the clutch throwout lever 16. It will thus be seen that movement of piston IIO to the right will rotate lever 20I in a counterclockwise direction and move clutch throwout lever 16 to the right to effect a disengagement of the clutch. The return of piston I I0 to the left under the influence of spring III will release the clutch and permit springs 38 in Fig. 1 to effect a clutch reengagement. A toothed member in the form of a pinion "206 'is rotatably mounted on shaft 201'and carr-ie's ratchet teeth 208. A lever 204 i'sj-ro'tat- 205. The lever 204 "depends" from shaft 201 and is adapted to be engaged by an abutment 2-I2 carried by piston rod H2. The abutment '2I2 is spaced to the left of the lever 204 so "that the initial movement to the right of the piston rod I I2 may be used to effect -clntch"disengagespring 2I4 urges .lever 2'04 to rotate ina clockwise direction.

In operation,- when the -piston H is moved to the right in Fig. 9 under the influence of nanifold suction the piston rod II2', which is a power operated member, is moved to the right and during the initial stages of this movement the lever I is rotated in acounterclockwise'direction and through rod 203 the clutch lever 16 is rotated and the clutch'disengaged. Additional movement of the piston IIO to the right brings the abutment 2 I 2 into engagement with the lever 204 which then rotates in a counterclockwise di rection and the pawl 205 thereon which is held in engagement with ratchet teeth 208 by spring 2I3 engages the teeth 208 and rotates the pinion 205 in a counterclockwise direction. Rotation 01 the pinion 206 causes clockwise rotation of the pinion 209 which rotates the rod 2I0 and per forms the functions of a crankshaft to effect linear movement of rod 2II. The linear movement is substantially equal to twice the length of rod 2). This linear movement causes a counterclockw se rotation of transmission shift lever 69to effect a speed ratio change in the transmission. When the valve I09-is clo ed and cylinder I01 vented, the spring I II returns the.

piston IIO to the left in Fig. 9. Piston rod H2 and abutment 2I2 are moved to the left. As the abutment 2I2 lifts away from lever 204, the spring 2I4 rotates the lever 204 in a clockwise direction and returns it to the position illustrated in Fig. 9 where it engages a fixed stop 2I5. A pawl 205 snaps over ratchet teeth 208 freely during this movement. Further movement of the piston rod H2 to the left retracts rod 203 and releases the clutch throwout lever 16.

Fig. 10 illustrates another form of the mechanical linkage. The piston H0 is slidably mounted in the cylinder I01 and urged to the right in Fig. 10 by the spring I I I. Manifold suction draws piston I I0 to the left in Fig. 10 as explained for the Fig. 3 form. The piston rod 220 is connected to one end of a lever 22! rotatably mounted at 222. The opposite end of the lever 22 I is connected to link 223 which engages clutch throwout fork 16. It will thus be seen that movement of piston IIO to the left in Fig. 10 rotates lever 22I in a counterclockwise direction and moves link 223 to the right thereby rotating clutch throwout lever 16 and disengaging the clutch. Return of piston IIO to the right in Fig. 10 under the influence of spring III permits the clutch to reengage. The vacuum cylinder housing I06 has a supplemental housing 224 secured thereto. The piston rod 220 extends through housing 224. A toothed member in the form of a pinion 225 is rotatably mounted on a shaft 226 extending transversely of housing 224. The piston rod 220 is provided with gear teeth on its ably-mounted on shaft 201'and carries-a pawl 2 sea -ta 'lower' edge and forms a power operated toothed "member in the form of a rack which engages the pinion 225. Thus linear movementof the piston re-c1220 induces rotation of -pinion 225. An abutment member 221 is carried by pinion 225. A

"lever 22s is keyed to the shaft226 and has a pawl 2 29 rotatably mountedon it; The abutment member 2'21 i's'adapted to engage" the pawl i229 and force the lever 228 and pawl 2'29 torotatewith' the pinion 225. 'A'1\7.el"23l i'sky d to shaft 226. Rotation'of pinion 225 in a counterclockwise direction induced by'the movement or piston'rod'220 to'the left in Fig. 1'0 causesa "counterclockwiserotation of abutment member '15 I lever 226 in a counterclockwise direction.

221. Member 227 engages pawl229 and rotates rotatesthe shaft 226 and lever 23I inv a counterclockwise direction. The size of. pinion 225 is selected so that the full stroke of piston-H0 'to the left will cause substantially a 180 movement ofpinion 22 5. This Will cause 2. 180 9 [tat ion of the lever 23I. The outer end 232 of the lever 23I has rotatably connected thereto a rod 233. Rotation of lever 23! through the 'arc'will cause the end 232 to induce linear motion in rod 233. The linear motion will be equal to twice the radius of lever 23I. The linear motion of rod 233 is transmitted through a rotatable lever 234, rotatably mounted at 235 to a rod 236 which connects the opposite end of rod 234 with transmission shift lever 69. Pawl 229 is provided with an extension 230 which carries a spring 231. The spring urges pawl 229 into engagement with abutment member 221 but permits the pawl to move out of the way of abutment member 221 when the latter is rotated in a clockwise direction. When the piston IIO has completed its stroke to the left in Fig. 10 under the influence of manifold suction and when the cylinder I06 is vented and spring II I returns the piston to the right in Fig. 10, a clutch reengagement occurs. The movement of the piston rod 220, lever 22 l, and rod 223 permits the clutch throwout springs 38 to reengage the clutch. This movement rotates the pinion 225 in a clockwise direction and the abutment member 221 freely rotates past the pawl 229. The spring 231 causes the pawl 229 to engage the abutment member 221 preparatory to the next power stroke of the piston I I0.

I claim:

1. An alternator mechanism adapted to be used in a motor vehicle speed change mechanism having a shiftable control element; said alternator mechanism including a power operated toothed member mounted for and adapted to be moved a predetermined distance in a first direction, a rotatably mounted member having teeth in drive receiving relationship with the teeth of said toothed member and being rotatable through an arc. of one hundred and eighty degrees in response to each movement of said first member through said predetermined distance in said first direction, and a crank drivingly connected to said rotatably mounted member and adapted to be connected to said shiftable control element for shifting said control element in opposite directions in response to successive movements of said power operated toothed member in its first direction.

2. An alternator mechanism adapted to be used in a motor vehicle speed change mechanism having a shiftable control element; said alternator mechanism including a first rotatably mounted toothed member, a power operated member mounted for linear movement for a predetermined distance in a first direction, cooperating elements carried respectively byfsaid members and adapted to impart rotation through a predetermined arc to said first member in response to linear movement of said power operated member through said predetermined distance in said first direction, a second rotatably mounted member having teeth in drive receiving relationship with the teeth of said first member and being rotatable through an arc of one hundred and eightly degrees in response to each rotation of said first member through said predetermined arc and a crank drivingly connected to said rotatably mounted member and adapted to be connected to said shiftable control element for shifting said control element in opposite directions in response to successive movements of said power operated member through said predetermined distance in said first direction.

3. An alternator mechanism adapted to be used in a motor vehicle speed change mechanism having a shiftable control element; said alternator mechanism including a power operated toothed member mounted for linear movement for a predetermined distance in a first direction, a rotatably mounted member having teeth in drive receiving relationship with the teeth of said toothed member and being rotatable through an arc of one hundred and eightly degrees in response to each movement of said first member through said predetermined distance in said first direction, and a crank drivingly connected to said rotatably mounted member and adapted to be connected 'to said shiftable control element for shifting said control element in opposite directions in response to successive movements of said power operated toothed member in its first direction. 1

' O'I'IO W. SCHOTZ.

REFERENCES CITED The following references are of record in the tile of this patent:

UNITED STATES PATENTS 

